论文信息 - The use of exploratory experimental designs combined with thermal numerical modelling to obtain a predictive tool for hybrid laser/MIG welding and coating processes

The use of exploratory experimental designs combined with thermal numerical modelling to obtain a predictive tool for hybrid laser/MIG welding and coating processes

Abstract While hybrid laser welding and coating processes involve a large number of physical phenomena, it is currently impossible to predict, for a given set of influencing factors, the shape of the molten zone and the history of temperature fields inside the parts. This remains true for complex processes, such as the hybrid laser/MIG welding process, which consists in combining a laser beam with a MIG torch. The gains obtained result essentially from the synergy of the associated processes: the stability of the process, the quality of the seam realized, and the productivity are increased. This article shows how, by means of a reduced number of experiments (8), it is possible to predict the shape of the molten zone and the temperature field inside parts, for a given window of influencing factors. This method consists in combining the method of exploratory experimental designs with a numerical modelling of the thermal phenomena that occurs during the process, by using the ‘heat equivalent source” approach [1] , [2] , [3] , [4] . Two validations of this method have been carried out: the first for a set of parameters inside the experimental design, and the other for a set of parameters that lies outside the experimental design, but inside the domain investigated.

[1] R. H. Myers,et al. Response Surface Methodology: Process and Product Optimization Using Designed Experiments , 1995 .

[2] D. Grevey,et al. Hot cracking in Al–Mg–Si alloy laser welding – operating parameters and their effects , 2005 .

[3] Eugen Cicala,et al. Dissimilar material joining using laser (aluminum to steel using zinc-based filler wire) , 2007 .

[4] S. Rouquette,et al. Estimation of a source term in a two-dimensional heat transfer problem: application to an electron beam welding, theoretical and experimental validations , 2007 .

[5] Christian Walz,et al. The Influence of Various Hybrid Welding Parameters on Bead Geometry Arc power and transfer mode greatly affect bead width, penetration, and reinforcement , 2004 .

[6] J. Goldak,et al. A new finite element model for welding heat sources , 1984 .

[7] J. Jouvard,et al. Optimisation of TA6V alloy surface laser texturing using an experimental design approach , 2008 .

[8] J. Goldak,et al. Computer modeling of heat flow in welds , 1986 .

[9] J. Jouvard,et al. The application of the random balance method in laser machining of metals , 2008 .

[10] D. Rosenthal. Mathematical Theory of Heat Distribution during Welding and Cutting , 1941 .

[11] Eugen Cicala,et al. Grooving by Nd:YAG laser treatment , 2000 .